An EMG-driven Musculoskeletal Model to Estimate Muscle Forces and Knee Joint Moments in Vivo

Overview

Journal J Biomech

Specialty Physiology

Date 2003 May 14

PMID 12742444

Citations 233

Authors

David G Lloyd

Thor F Besier

Affiliations

Soon will be listed here.

Abstract

This paper examined if an electromyography (EMG) driven musculoskeletal model of the human knee could be used to predict knee moments, calculated using inverse dynamics, across a varied range of dynamic contractile conditions. Muscle-tendon lengths and moment arms of 13 muscles crossing the knee joint were determined from joint kinematics using a three-dimensional anatomical model of the lower limb. Muscle activation was determined using a second-order discrete non-linear model using rectified and low-pass filtered EMG as input. A modified Hill-type muscle model was used to calculate individual muscle forces using activation and muscle tendon lengths as inputs. The model was calibrated to six individuals by altering a set of physiologically based parameters using mathematical optimisation to match the net flexion/extension (FE) muscle moment with those measured by inverse dynamics. The model was calibrated for each subject using 5 different tasks, including passive and active FE in an isokinetic dynamometer, running, and cutting manoeuvres recorded using three-dimensional motion analysis. Once calibrated, the model was used to predict the FE moments, estimated via inverse dynamics, from over 200 isokinetic dynamometer, running and sidestepping tasks. The inverse dynamics joint moments were predicted with an average R(2) of 0.91 and mean residual error of approximately 12 Nm. A re-calibration of only the EMG-to-activation parameters revealed FE moments prediction across weeks of similar accuracy. Changing the muscle model to one that is more physiologically correct produced better predictions. The modelling method presented represents a good way to estimate in vivo muscle forces during movement tasks.

Citing Articles

Soft back exosuit controlled by neuro-mechanical modeling provides adaptive assistance while lifting unknown loads and reduces lumbosacral compression forces.

Moya-Esteban A, Refai M, Sridar S, van der Kooij H, Sartori M Wearable Technol. 2025; 6:e9.

PMID: 40071245 PMC: 11894419. DOI: 10.1017/wtc.2025.3.

Facial expression recognition through muscle synergies and estimation of facial keypoint displacements through a skin-musculoskeletal model using facial sEMG signals.

Shu L, Barradas V, Qin Z, Koike Y Front Bioeng Biotechnol. 2025; 13:1490919.

PMID: 40013307 PMC: 11861201. DOI: 10.3389/fbioe.2025.1490919.

Research on Upper Limb Motion Intention Classification and Rehabilitation Robot Control Based on sEMG.

Song T, Zhang K, Yan Z, Li Y, Guo S, Li X Sensors (Basel). 2025; 25(4).

PMID: 40006285 PMC: 11859407. DOI: 10.3390/s25041057.

Assessing low-back loading during lifting using personalized electromyography-driven trunk models and NIOSH-based risk levels.

Refai M, Varrecchia T, Chini G, Ranavolo A, Sartori M Front Bioeng Biotechnol. 2025; 13:1486931.

PMID: 39991136 PMC: 11842350. DOI: 10.3389/fbioe.2025.1486931.

Improving movement decoding performance under joint constraints based on a neural-driven musculoskeletal model.

Pan L, Yan X, Yue S, Li J Med Biol Eng Comput. 2025; .

PMID: 39934506 DOI: 10.1007/s11517-025-03321-1.